Magnetic-disc unit

ABSTRACT

In a magnetic disk apparatus including a plurality of magnetic disks mounted on a spindle, arms supporting magnetic heads, a rotary actuator for the arms, and a housing having an arcuate-shaped shroud, the improvement wherein gaps between the shroud and the sides of outer peripheries of the magnetic disks are larger than 0.1 mm and less than 0.6 mm. An open space is located, downstream of the arms, with respect to an air flow on surfaces of the magnetic disks, the open space being devoid of the shroud. An opening is provided in the shroud, upstream of the arms with respect to the air flow and having a greater width than a width of the gaps defined between the magnetic disks and the shroud, and a bypass channel is provided which communicates between the opening and the open space.

CROSS REFERENCE TO RELATED APPLICATION

[0001] This is a continuation-in-part of U.S. application Ser. No. 09/247,550, filed Feb. 10, 1999, and a continuation-in-part of U.S. application Ser. No. 09/356,056, filed Jul. 16, 1999, the subject matter of each of the aforementioned application being incorporated by reference herein.

BACKGROUND OF THE INVENTION

[0002] The present invention relates to a rotary recording apparatus for reading and writing data from and to a rotating disc by means of a magnetic head, an optical head or the like, and in particular to a magnetic disc unit which can reduce fluid oscillation induced on a rotating disc so as to carry out positioning with a high degree of accuracy.

[0003] It a magnetic disc unit, these days, it is required to increase the capacity of memory by increasing the processing speed, and accordingly, the rotational speed of a disc has been gradually increased. However, an increase in the rotational speed, increases disc oscillation due to a fluid force caused by rotation so as to raise a new problem that the degree of positioning accuracy is lowered.

[0004] Conventionally, as disclosed in Japanese Laid-Open Patent No. S59-72680, a shroud is provided around the outer periphery of a disc with a predetermined gap between the disc and the shroud in order to reduce bounce (which well be hereinbelow referred to as “flutter”) of the disc. In this document there is described that the distance between the inner wall of the shroud and the outer periphery of the disc is changed from 12 mm to 10 mm, and as a result, the amplitude of oscillation is decreased from about 20 ft to 10 ft. Further, if the distance is decreased to 6 mm, the amplitude of oscillation is decreased to 15 ft, and if the distance is set to be less than 3 mm, the amplitude of oscillation becomes 8 ft which is relatively small. That is, if the outer periphery of the magnetic disc and the inner wall of the shroud is set to a value below 3 mm, the oscillation can be minimized.

[0005] Further, in Japanese Laid-Open Patent No. H9-204767, there is discloses a gap between a shroud and a magnetic disc which set to be 0.1 mm in order to prevent liquid lubricant with which the outer surface of the magnetic disc is coated, from scattering.

[0006] It is noted that, in the above-mentioned Japanese Laid-Open Patent No. S59-72680, there is disclosed a gap between the shroud and the disc which is 2 mm at maximum.

[0007] Further, in Japanese Laid-Open Patent No. H9-204767, there is disclosed a gap between the shroud and the disc which is 0.1 mm at maximum.

[0008] By the way, in a magnetic disc unit, a higher data transfer velocity (data rate) is desired in order to obtain a larger storage capacity. Thus, the rotational speed of a disc has been gradually increased up to now, and it is anticipated that the rotational speed will be further increased in future. An increase in rotational speed of a disc increases flutter which is oscillation of a disc, and accordingly, would mainly contribute to increase errors in positioning of a magnetic head. Thus, it has been required to reduce the oscillation.

[0009] Thus, there has mainly been two ways for reducing flutter of a disc as follows: First, a fluid force serving as an excitation source is reduced. Precisely, the pressure distribution is made to be uniform over the surface of a disc. Second, the stiffness of a disc is increased in order to decrease oscillation of a disc.

[0010] Although the thickness of a disc may be increased to increase the stiffness of the disc, an increase in the thickness thereof causes a disc unit to have a larger size, and accordingly, it is unpreferable.

OBJECT AND SUMMARY OF THE INVENTION

[0011] An object of the present invention is to provide a rotary recording apparatus which can, on one hand, prevent flutter causing errors in positioning from increasing even though the rotational speed becomes higher, and which can, on the other hand, enhance the degree of positional accuracy for coping with a large storage capacity.

[0012] That is, according to the present invention, there is provided a large capacity magnetic disc unit which can reduce a fluid force serving as an excitation source so as to prevent occurrence of flutter in order to restrain occurrence of noise or the like, and which can read and write data from and onto a disc with a high degree of accuracy. Specifically, a shroud (outer wall) is provided around the entire periphery of a rotating disc, except an insertion part thereof for a carriage arm, and a gap between the shroud and the outer periphery of the disc is set to be not less than 0.1 mm but not greater than 0.6 mm.

[0013] An air stream induced during rotation of a disc causes a pressure differential between the upper and lower surfaces of the disc, which causes excitation of the disc, resulting in flutter of the disc. If the gap between the shroud and the disc is set to be narrower than a predetermined value, air on the upper and lower surfaces of the disc is isolated so as to reduce the pressure differential.

[0014] With this arrangement, it is possible to reduce the amplitude of flutter, and accordingly, the degree of accuracy for positioning a magnetic head even in a high speed recording apparatus can be enhanced.

BRIEF DESCRIPTION OF THE DRAWINGS

[0015]FIG. 1A is a perspective view illustrating a disc unit to which the present invention is applied;

[0016]FIG. 1B is a top view illustrating the disc unit shown in FIG. 1A;

[0017]FIG. 2 is a sectional view illustrating a disc part, for defining a gap between a shroud and a disc;

[0018]FIG. 3 is a view showing a relationship between an amplitude of flutter and a gap between the shroud and the disc;

[0019]FIGS. 4A to 4D are contour maps of air pressure differential on the front and rear surfaces of a disc, which is obtained through analysis;

[0020]FIG. 5 is a relationship between an amplitude of flutter and a gap between a shroud and a disc; and

[0021]FIG. 6 is a top view of a magnetic disc unit according to another embodiment of the present invention.

DESCRIPTION OF THE EMBODIMENTS

[0022] Explanation will be made of a first embodiment of the present invention with reference to FIGS. 1a to 4 d. Referring to FIGS. 1A and 1B, discs 1 are stacked on a spindle 2, and a magnetic head 3 for recording and reproducing data is carried on a slider 4 which is supported by a magnetic head support mechanism 5 connected to a guide arm 6. A carriage 9 is composed of the guide arm 6, a pivot bearing 7 and a voice coil motor (which will be hereinbelow referred to as “VMC”) 8, and the guide arm 6 is rotated by the VMC 8 around the pivot bearing 7. Further, these elements are set on a casting base 10 which is surrounded by a wall (shroud 20). A gap between the outer peripheries of the discs 1 and the inner wall of the shroud 20 is maintained at a predetermined distance (which will b4 referred to as “disc-shroud gap”). The shroud 20 and the base 10 are made of the same casting material, being integrally incorporated with each other.

[0023] The shroud 20 is formed therein with an opening 30 for introducing the guide arm 6 therethough onto a surface of a disc 1. The opening angle of the opening 30 is selected so as to be minimized while to allow the arm to be simply assembled and to prevent the arm from making contact with the shroud even through the head is shifted from the inner periphery to the outer periphery of the disc. In this embodiment, the opening angle is set to about 45 deg.

[0024] A wall is formed along the entire periphery of the base 10 of the unit. Further, this wall serves as a part of the shroud 20 surrounding the outer peripheries of the discs 1. However, the shroud 20 is arranged to branch off from the wall in the vicinity of the opening 30 so as to surround the discs 1.

[0025] Meanwhile, the wall serves as a surrounding wall 40 for surrounding the carriage 9 so as to hermetically enclose the unit. Repeatedly, the wall surrounding the discs 1 will be hereinbelow defined and referred to as the shroud 20. According to the present invention, the gap between the shroud 20 and the end faces of the discs 1 is regulated within a predetermined range so as to reduce the amplitude of flutter which would occur during rotation of the disc at a high speed, in order to restrain occurrence of noise. Detailed explanation will be hereinbelow made of this measure.

[0026] Referring to FIG. 2 which is a sectional view along line A-A in FIG. 1B, the definition to the disc-shroud gap will be clarified.

[0027] As shown in FIG. 2, the spindle motor 2 is mounted on the base 10, having a shaft on which the discs 1 are stacked. The base 10 is incorporated with the shroud 20, being integrally molded therewith. The inner wall 21 of the shroud 20 is arranged along the entire periphery of the discs with a predetermined gap being held from the edge faces 11 of the discs 1 (this gap will be hereinbelow referred to as “disc-shroud gap”), except that the opening (which is not shown in FIG. 2) for introducing the arm 6 is formed in a part where the arm 6 of the carriage 9 is introduced onto a surface of a disc 1. The inner wall of the shroud is substantially circular, having a center which is substantially aligned with the rotating center of the discs 1 or the spindle motor 2. Accordingly, the above-mentioned disc-shroud gap is substantially uniform around the entire peripheries of the discs 1, except that the opening, that is, the insertion part for the arm 6, where no shroud 20 is formed.

[0028] Referring to FIG. 3, there are shown results of measurements for relationship between the disc-shroud gap and the amplitude of flutter. Specifically, with the use of magnetic discs having an outer diameter of 3.5 inches, the discs were rotated at 7,200 rpm while amplitudes of flutter were measured by a displacement gage utilizing LDV (laser Doppler Velocity) while the disc-shroud gap is changed from 0.2 mm, to 0.4 nun, 0.6 mm, 0.81.2 mm, 2.5 mm, 4mm and to 6 mm. The results of the measurements, which are averaged and normalized, that is, are non-dimensional values, are shown in FIG. 3.

[0029] In the figure, circular, triangular and square spots denote various flutters-having different frequencies. As clearly understood from these results of measurements, the amplitude of flutter is decreased as the disc-shroud gap is decreased to a value less than 0.6 mm. Further, the amplitude of flutter is not appreciably decreased in a range from 0.6 mm to 6 mm. Meanwhile, in the case of less than 0.6 mm, if the disc-shroud gap is decreased to 0.4 mm and to 0.2 mm, the amplitude of flutter can be reduced, remarkably. Specifically, if the shroud gap is 0.2 mm, the amplitude of flutter can be decreased to a value which is about {fraction (1/10)} of the amplitude of flutter obtained with a disc-shroud gap of 0.6 mm.

[0030] In this embodiment, the disc-shroud gap is set to 0.4 mm. With this arrangement, the amplitude of flutter can be reduced to about a half of that obtained at a disc-shroud gap of about 1 mm. Of course, a disc-shroud gap of about 0.5 mm is also effective. It is desirable that the disc-shroud gap is narrower since the amplitude of flutter can become smaller. However, in view of the assembly of a disc unit, the narrower the disc-shroud gap, the more the difficulty in assembling the magnetic disc unit.

[0031] Further, it would be practically impossible to set the disc-shroud gap to a value less than 0.1 mm, in view of a diametrical tolerance (0.05 mm) of discs which are available at present and the erection tolerance between discs and spindles. In view of the above-mentioned facts, it has been understood that the flutter can be reduced by setting the disc-shroud gap in a range which is not less than 0.1 mm but not greater than 0.6 mm.

[0032]FIGS. 4A to 4D show contour lines of air pressure differentials between the outer and rear surfaces of a rotating disc, which were obtained from results of flow analysis in such a condition that the disc-shroud gap is narrowed. FIGS. 4a to 4 d show those with a disc-shroud gap of 2 mm, 1 mm, 0.5 mm and 0.2 mm, respectively.

[0033] As understood from these figures, contour lines have crest peaks on the outer peripheral side of the disc in the case of a disc-shroud gap of 2 mm or 1 mm. These pressure differentials becomes excitation forces applied to the disc, causing the disc to flutter. Meanwhile, in the case of a small disc-shroud gap of 0.5 mm or 0.2 mm, no contour lines having crest peaks of pressure differentials causing occurrence of flutter, are found. In other words, no pressure differentials are produced, and accordingly, the amplitude of flutter becomes smaller. These results well follow the results of experiments shown in FIG. 3, qualitatively and quantitatively. Thus, it has been also understood from the results of this analysis that a disc-shroud gap of less than 0.5 mm can effectively restrain occurrence of flutter.

[0034] Reference Example

[0035] A high speed magnetic disc unit in which the outer diameter of discs is 2.5 inches, and the rotational speed is 12,600 rpm, and the opening 30 has an opening angle of 140 deg. was prepared, and tested for flutter in the following measuring conditions: Rotational speed: 12,600 rpm Disc thickness: 0.8 mm

[0036] Measuring position: topmost and outermost of disc

[0037] Measuring Method: flutter amplitudes were measured at five low frequencied by LVD Averaged values each obtained from the five measured amplitudes were comparatively considered (Refer to FIG. 5)

[0038] The results of these measurements show that a smaller disc-shroud gap is effective for reducing flutter, similar to the effects mentioned before. In this example, if the disc-shroud gap becomes less than 0.4 mm, the flutter reducing effects is appreciable. Thus, the disc-shroud gap is set to 0.4 mm. Accordingly, the amplitude of flutter can be reduced by about 10%. Further, if the disc-shroud gap is set to 0.2 mm, the flutter can be reduced by about 50%.

[0039] In the same example, even if the opening angle of the opening 30 is set to 45 deg., 65 deg. and to 140 deg. respectively, no distinctive difference was appreciated in the effects of reducing the amplitude of flutter by decreasing the disc-shroud gap. Namely, it has been experimentally confirmed that the flutter can be reduced by decreasing the disc-flutter gap if the opening angle was changed from 45 deg. to 140 deg. Thus, the opening angle of the opening 30 is set to about 140 deg. in view of simplicity of the assembly of the apparatus. The lower limit values of the disc-shroud gap must be set to a value greater than 0.1 mm in view of the manufacturing tolerance of outer diameter dimensions of discs and the erection tolerance of the disc unit.

[0040] Although difference between the disc-shroud gaps of 0.6 mm and 0.4 mm for reducing flutter seems to be appreciable, if these gaps are normalized by the diameters of the discs, about {fraction (1/150)} for a 2.5 inch disc and about {fraction (1/130)} for a 3.5 inch disc, which are nearly equal to each other, can be obtained. In this example, the flutter can be also reduced while a high speed magnetic disc unit having a large storage capacity can be obtained.

[0041] Further, with the provision of a pocket adapted to accommodate an air filter for purifying air flowing into the unit, in a part of the shroud, or the provision of a finger insertion pocket for removal of a disc the disc-shroud gap becomes large in that part in comparison with the other part of the shroud. Even in this case, it has been confirmed that effects similar to those mentioned above can be also obtained.

[0042] Although, in the first embodiment, it has been explained that the shroud 20 is made of the same casting material as that of the base 10, and is integrally incorporated with the base 10, the shroud 20 may be formed, independent from the base 10, in order to enhance the processing accuracy and the processing performance thereof, and thereafter, it may be assembled to the base 10.

[0043] Alternatively, the shroud may be machined. Further, even through the disc-shroud gap is different between the uppermost and lowermost ones of the stacked discs due to a die drawing gradient of the base mold dies, it had been confirmed that the same technical effects and advantages as that of the first embodiment may be obtained if the minimum disc-shroud gap is set to a value less than 0.6 mm or 0.4

[0044] With the provision of such an arrangement according to the present invention, a cylindrical shroud is provided around magnetic discs stacked on the shaft of a spindle motor, and a gap between the shroud and the outer end faces of the discs is set in a predetermined range (not less than 0.1 but not greater than 0.6 mm), a high speed and large storage capacity magnetic disc unit can be provided.

[0045] In an embodiment shown in FIG. 6, the gap between the side of the disk stack 1 and the shroud 20 is 0.1 mm to 0.6 mm. Also, an opening 12 c is provided upstream of the arms 6, and an opened space 11 is provided downstream of the arms 6, the opening 12 c and the opened space 11 are communicated with each other through a bypass channel 15 having a linear section which extends from the opening 12 c with a width D and a depth greater than 5 D in a direction parallel to the rotating shaft on which the plurality of disks are mounted. The bypass channel is defined by side surfaces of a motor cover 8 a for a voice coil motor 8 and inner walls of the housing 40, and the shroud 20 is formed between the voice coil motor and the disk stack 1 upstream of the arms 4. The motor cover 8 a is desirably closed so as to prevent airflow in the bypass channel 15 from entering into the voice coil motor. However, a closed structure is formed only in a part around the opening 12 c while the motor cover 8 a may be eliminated. Instead, the voice coil motor 8 is directly located without the motor cover 21 a. With this arrangement, the bypass channel 15 will become less effective in reducing fluctuations of flow velocity but the necessity of the provision of the motor cover 8 a can be eliminated so as to be advantageous in productivity.

[0046] Even in this embodiment, the small gap between the shroud 20 and the disk stack 1 can also reduce flutter of disks. Also, the bypass channel providing communication between the opening 12 c and the opened space 11 makes it possible to prevent fluctuations in pressure difference between high pressure upstream of the arms and low pressure downstream of the arms. Thereby, it becomes possible to reduce flutter and to suppress varying forces, which are referred to as wind turbulence causing oscillation of the arms. Thus, reduction of the gap between the shroud 20 and the disk stack 1 and adoption of the bypass channel 21 make it possible to reduce flutter and suppress wind turbulence of the arms. Combined use of these two techniques suppresses flutter and vibrations of arms to enable realizing a magnetic disk apparatus of high-speed rotation. 

What is claimed is:
 1. In a magnetic disk apparatus including a plurality of magnetic disks mounted on a spindle, arms supporting thereon magnetic heads and held on surfaces of said magnetic disks, a rotary actuator for moving said arms, and a housing having an arcuate-shaped shroud, which is concentric with said magnetic disks to surround sides of said magnetic disks so as to permit movement of said arms, the improvement wherein gaps between said shroud and the sides of outer peripheries of said magnetic disks are larger than 0.1 mm and less than 0.6 mm, and wherein an open space is located, downstream of said arms, with respect to an air flow which is generated by revolution of said magnetic disks on surfaces of said magnetic disks, said open space being devoid of said shroud, an opening is provided in said shroud, upstream of said arms with respect to said air flow and having a greater width than a width of the gaps defined between said magnetic disks and said shroud, and a bypass channel is provided which communicates between said opening and said open space.
 2. The magnetic disk apparatus according to claim 1, wherein the plurality of magnetic disks are stacked on a single motor shaft, have an outer diameter of 3.5 inch, and are rotated at a rated rotating speed higher than 7600 rpm.
 3. The magnetic disk apparatus according to claim 1, wherein the plurality of magnetic disks are stacked on a single spindle motor shaft, having an outer diameter of 2.5 inch and is rotated at a rated rotating speed higher than 12000 rpm, and wherein the gaps between the sides of the respective magnetic disks is larger than 0.1 mm and less than 0.4 mm.
 4. In a magnetic disk apparatus including magnetic disks mounted on a spindle, arms supporting thereon magnetic heads and held on surfaces of said magnetic disks, a rotary actuator for moving said arms, and a housing having an arcuate-shaped shroud, which is concentric with said magnetic disks to surround sides of said magnetic disks so as to permit movements of said arms, the improvement wherein gaps between said shroud and the sides of said magnetic disks are larger than 0.1 mm and less than 0.6 mm, and wherein an open space is located downstream of said arms with respect to an air flow which is generated by revolution of said magnetic disks on surfaces of said magnetic disks, said open space being devoid of said shroud, an opening is provided on said shroud upstream of said arms with respect to said air flow and having a greater width than a width of the gaps defined between said magnetic disks and said shroud, and a bypass channel is provided which communicates between said opening and said open space, and wherein said bypass channel is defined between a cover which constitutes a part of said shroud and covers a voice coil motor for driving said rotary actuator, and an inner wall of said housing said bypass channel having a linear section of a predetermined length extending from said opening.
 5. The magnetic disk apparatus according to claim 4, wherein the plurality of magnetic disks are stacked on a single motor shaft, have an outer diameter of 3.5 inch, and are rotated at a rated rotating speed higher than 7600 rpm.
 6. The magnetic disk apparatus according to claim 4, wherein the plurality of magnetic disks are stacked on a single spindle motor shaft, have an outer diameter of 2.5 inch and are rotated at a rated rotating speed higher than 12000 rpm, and wherein the gaps between the sides of the respective magnetic disks is larger than 0.1 mm and less than 0.4 mm.
 7. The magnetic disk apparatus according to claim 4, wherein said bypass channel has a depth greater than 5 D in a direction parallel to the rotating shaft where D is a width of the linear section.
 8. The magnetic disk apparatus according to claim 4, wherein said bypass channel has the linear section having a length greater than 5 D where D is a width of the linear section.
 9. The magnetic disk apparatus according to claim 4, wherein said bypass channel has a depth greater than 5 D in a direction parallel to the spindle and the linear section has a length greater than 5 D where D is a width of the linear section.
 10. The magnetic disk apparatus according to claim 4, wherein said cover covers at least a side surface of the voice coil motor.
 11. The magnetic disk apparatus according to claim 4, wherein said cover is a component which encloses a coil section of the voice coil motor and at least a side surface of which is closed to prevent airflow from flowing into the voice coil motor from the bypass channel.
 12. In a magnetic disk apparatus including a plurality of magnetic disks stacked on a spindle, arms supporting thereon magnetic heads and inserted between said magnetic disks, a rotary actuator for moving said arms, and a housing having an arcuate-shaped shroud, which is concentric with said magnetic disks to surround sides of said magnetic disks so as to permit movements of said arms, the improvement wherein gaps between said shroud and the magnetic disks amount to {fraction (1/150)} to {fraction (1/890)} of a diameter D of the magnetic disks, and wherein an open space is located downstream of said arms with respect to an air flow, which is generated by revolution of said magnetic disks to flow on surfaces of said magnetic disks, said open space being devoid of said shroud, an opening is provided in said shroud upstream of said arms with respect to said air flow and having a width greater than that of the gaps defined between said magnetic disks and said shroud, and a bypass channel is provided which communicates between said opening and said open space.
 13. The magnetic disk apparatus according to claim 12, wherein said bypass channel is defined between a cover which constitutes a part of said shroud and covers a voice coil motor for driving said rotary actuator, and an inner wall of said housing said bypass channel having a linear section of a predetermined length extending from said opening.
 14. The magnetic disk apparatus according to claim 13, wherein the plurality of magnetic disks are stacked on a single motor shaft, have an outer diameter of 3.5 inch, and are rotated at a rated rotating speed higher than 7600 rpm.
 15. The magnetic disk apparatus according to claim 13, wherein the plurality of magnetic disks are stacked on a single spindle motor shaft, have an outer diameter of 2.5 inch and are s rotated at a rated rotating speed higher than 12000 rpm, and wherein the gaps between the sides of the respective magnetic disks is larger than 0.1 mm and less than 0.4 mm.
 16. The magnetic disk apparatus according to claim 13, wherein said bypass channel has a depth greater than 5 D in a direction parallel to the rotating shaft where D is a width of the linear section.
 17. The magnetic disk apparatus according to claim 13, wherein said bypass channel has the linear section having a length greater than 5 D where D is a width of the linear section.
 18. The magnetic disk apparatus according to claim 13, wherein said bypass channel has a depth greater than 5 D in a direction parallel to the spindle and the linear section has a length greater than 5 D where D is a width of the linear section.
 19. The magnetic disk apparatus according to claim 13, wherein said cover covers at least a side surface of the voice coil motor.
 20. The magnetic disk apparatus according to claim 13, wherein said cover is a component which encloses a coil section of the voice coil motor and at least a side surface of which is closed to prevent airflow from flowing into the voice coil motor from the bypass channel. 